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The tiny dwarf galaxy Fornax UCD3 (inset) orbits around a giant elliptical galaxy called NGC 1399. Astronomers used the Very Large Telescope in Chile to discover a supermassive black hole at UCD3’s heart.

Courtesy of NASA/STScI/ESO/Afanasiev et al.

A small galaxy some 70 million light-years from Earth has been hiding a big secret.

This week, astronomers announced they’d found a supermassive
black hole (SMBH) lurking at the center of a galaxy called Fornax UCD3. It’s an odd place for such a giant black hole to survive.

Supermassive black holes commonly thrive at the heart of large galaxies —
including our own Milky Way — but they’re mostly absent in dwarf galaxies like UCD3. Dwarf galaxies are typically loose assemblages of stars, sometimes with intermediate black holes in the center.

For instance, the Large Magellanic Cloud, the largest of the “dwarf galaxies” orbiting the Milky Way, lacks a supermassive black hole. This also typically makes dwarf galaxies diffuse. The Large Magellanic Cloud has a relatively paltry 30 billion stars spread across 14,000 light years.

But this recently discovered system is what astronomers call an ultracompact dwarf galaxy. It packs a lot of stars in a very small space. This tiny galaxy is no more than 300 light years across, but has a whopping 100 million stars. For scale, the Milky Way is around 150,000 light years across with hundreds of billions of stars.

Yet scientists were surprised to find a voracious black hole with the mass of 3.5 million suns at UCD3’s heart. That’s around three-quarters the size of Sagittarius A*, the
black hole at the center of our own galaxy.

Astronomers aren’t sure how supermassive black holes end up in ultracompact dwarfs. It could be that UCD3 is the remnant of a larger galaxy that was stripped of its stars by a close brush with another galaxy. Or, perhaps UCD3 formed when several super groups of stars joined together.

Whatever its origin, UCD3’s black hole is one of only a handful ever found in these dwarfs, and it makes up 4 percent of the mass of its galaxy. Most supermassive black holes weigh less than one percent the mass of their galaxy.

The discovery was made using the European Southern Observatory’s Very Large Telescope in northern Chile. Astronomers outfitted the telescope with a sensor that measures cosmic light in infrared. This allowed them to monitor how fast stars rotated around the galaxy.

The scientists say they deduced the black hole’s presence from the way stars seemed to be spread.

“To be able to say with complete assurance that this hypothesis is correct, we need to discover more supermassive black holes in ultracompact dwarfs,” lead author Anton Afanasiev said in a press release. Afanasiev and his colleagues at Lomonosov Moscow State University published their research in the
Monthly Notices of the Royal Astronomical Society.

We’ve only known of these tiny galaxies for a relatively short time, so discovering more examples could help astronomers determine if supermassive
black holes are common or rare at the center of ultracompact dwarfs.

Finding more could be a challenge because of their size. But ESO is up to the task—so we might expect a whole lot more in the coming decades.

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5 comments

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Added 2 weeks ago

Martin Mengel

If the author had started out saying that it was a black hole in the middle of a dwarf galaxy, then the oxymoron would not really exist. It is only because a significant material fact was omitted that the term seemed contradictory. Thought of the day. If black holes vary in "size"/mass, does that mean that the concept of a singularity being therein has no reality?
pay for essay here.

Added 2 weeks ago

LAN Manic

Eric - let's see... the volume of a sphere is 4/3pi*r^3. Converting the diameter to light days, we have about 110,000 ld. Halve that for the radius (55,000) and the sphere volume equation comes out to about 689 trillion ld^3. Divide that by 100million and I get a star about every 6.9 million ld^3 or a star about every 1/6 ly^3. Confirm?

Added 2 weeks ago

BRUCE MAIER

That the black hole is 4% means that the possibility that it is a merger (which would keep the % lower) is less likely than it was stripped of stars (with only those closest to the black hole remaining). Perhaps this resembles the a galactic core? (without the spiral arms or disc).

Added 3 weeks ago

Eric George

My math must be wrong but I came up with the galaxy averaging a star every cubic light day? I would appreciate if someone could come up with the correct figure...

Added 3 weeks ago

Samuel Davis III

After many posts herein I,all kidding aside,would like to know why can't we(as a race)randomly seed other heavenly bodies?